CN112538488B - Application of NbSMG7 gene in regulation and control of plant virus resistance and transgenic plant cultivation method - Google Patents
Application of NbSMG7 gene in regulation and control of plant virus resistance and transgenic plant cultivation method Download PDFInfo
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Abstract
The invention discloses an application of a Nicotiana benthamiana NbSMG7 gene in regulation and control of plant virus resistance and a transgenic plant cultivation method, wherein the virus is cucumber green mottle mosaic virus, and the sequence of a transcript of the NbSMG7 gene is shown as SEQ ID NO: 1. The invention clones NbSMG7 gene in Nicotiana benthamiana, constructs the gene into YFP-NbSMG7 vector with fluorescent label, and infects tobacco after transferring the YFP-NbSMG7 vector into agrobacterium to carry out genetic transformation of tobacco, thus obtaining YFP-NbSMG7 transgenic plant. The obtained burley tobacco overexpression YFP-NbSMG7 plant can obviously block the infection of cucumber green mottle mosaic virus.
Description
Technical Field
The invention relates to the technical field of genetic engineering, in particular to a method for cultivating a stable-genetic anti-cucumber green mottle mosaic virus NbSMG7 transgenic plant.
Background
Cucumber Green Mottle Mosaic Virus (CGMMV) belongs to Virgaviridae (Virgaviridae) and tobacco mosaic virus (Tobamovirus), can infect cucurbitaceae crops such as Cucumber, cucurbit, melon, watermelon and the like, cause plant growth retardation, leaf chlorosis, mottle, fruit discoloration and fibrosis, cause serious loss, and is an important plant quarantine pest in China.
CGMMV is positive-sense single-stranded RNA virus, has the total length of about 6400nt, and encodes 4 proteins, namely a replicase with 129kD, a replication-related protein with 186kD, a motor protein with 29kD and a coat protein with 17.4 kD.
The harm of CGMMV to cucurbits is a worldwide problem, and no effective chemical agent for preventing and treating CGMMV exists at present. The harm of the CGMMV can be reduced to a certain extent by a conservative method, such as using sterilized seeds, cultivating robust plants by improving a cultivation technology, eradicating diseased single plants in time in the field, cutting off a virus propagation carrier by using an insecticide, and the like. However, no medicament and disease-resistant plant with prevention and treatment effects on CGMMV have been developed at the present stage, and research shows that the seed treatment measures are not efficient and stable. In addition, the grafting technology is a farming operation technology generally applied to cucurbit crops in production and is also one of powerful measures for preventing and controlling plant diseases and insect pests, however, the CGMMV is reported to be transported to scions of watermelon stocks, so that the CGMMV can potentially become a source of initial infection in fields through grafting propagation.
Disclosure of Invention
The first purpose of the invention is to provide an application of the NbSMG7 gene of the Nicotiana benthamiana in regulating and controlling plant virus resistance.
The second purpose of the invention is to provide a method for cultivating the Nicotiana benthamiana NbSMG7 high-expression plant.
In order to achieve the purpose, the technical scheme adopted by the invention is as follows:
the application of the NbSMG7 gene in regulation and control of plant virus resistance, wherein the virus is cucumber green mottle mosaic virus.
Specifically, by cloning NbSMG7 gene in the Bunsen tobacco, constructing the NbSMG7 gene into YFP-NbSMG7 vector with a fluorescent label, and infecting tobacco after transferring the YFP-NbSMG7 vector into agrobacterium, the obtained Bunsen tobacco overexpressing YFP-NbSMG7 plant can obviously block the infection of cucumber green mottle mosaic virus.
Wherein the transcript sequence of the NbSMG7 is shown as SEQ ID NO. 1.
A method for cultivating a cucumber green mottle mosaic virus resistant NbSMG7 transgenic plant comprises the following steps: by an agrobacterium transformation method, NbSMG7 gene is introduced into a target plant to obtain a transgenic plant with high expression of NbSMG7 of Nicotiana benthamiana.
The method specifically comprises the following steps:
(1) obtaining a Nicotiana benthamiana plant, extracting RNA from leaves of the Nicotiana benthamiana plant by using a Trizol method, removing genome DNA in an RNA sample, and performing reverse transcription to obtain cDNA;
(2) the primer pair NbSMG7-F and NbSMG7-R is shown as SEQ ID NO:2-3, cDNA is used as a template for PCR amplification, and the used primer sequence is as follows:
NbSMG7-F:atgatgaccattccaatgga,
NbSMG7-R:cacaaacaaacggccttc;
(3) constructing the amplification product on an n-YFP vector to obtain a YFP-NbSMG7 recombinant plasmid;
(4) transferring 1 mul of recombinant plasmid and 100 mul of agrobacterium-infected mixture into an electric shock cup, performing electric shock transformation by using an electric shock device at 2500V, adding LB culture medium, culturing for 2 hours, recovering, and then coating the mixture on a resistant culture medium to screen and obtain agrobacterium with YFP-NbSMG7 recombinant plasmid;
(5) infecting tobacco leaves with agrobacterium with recombinant plasmid, performing differentiation culture to obtain callus, performing rooting culture to obtain plantlet, and transferring for continuous culture;
(6) after the continuously cultured plantlets grow stably, taking a leaf sample, extracting DNA from plant leaves by using a CTAB method, performing PCR amplification by using the extracted DNA as a template, and determining whether YFP-NbSMG7 is successfully transformed; the primer sequences used were:
35S-F:cgcaagacccttcctctatataaggaa,
NbSMG 7-R: CACAAACAAACGGCCTTC, respectively; as shown in SEQ ID NO. 4 and SEQ ID NO. 3,
extracting total protein from the samples, performing SDS-PAGE gel electrophoresis, and determining that the YFP-NbSMG7 with a YFP fluorescent label is expressed by the plants by using GFP antibody to perform Western blot; and reserving seeds of transgenic tobacco successfully transformed and overexpressed with YFP-NbSMG 7.
According to the characteristics of the CGMMV genome, the genome contains a Premature Termination Codon (PTC), and a Nonsense-mediated mRNA degradation (NMD) mechanism is utilized: it has the function of targeting PTC RNA, resulting in cleavage and degradation of the target RNA. The NbSMG7 gene cloned in the invention is a key factor of NMD pathway, and can participate in NMD pathway, target RNA, and cause the RNA to be cut and degraded. The invention obtains the Nicotiana benthamiana overexpression YFP-NbSMG7 plant through genetic transformation, and the CGMMV infection can be effectively resisted through verification, and compared with the wild Nicotiana benthamiana plant, the virus RNA expression quantity of the CGMMV in the YFP-NbSMG7 transgenic plant is reduced by about 50-75%.
Compared with the prior art, the invention has the outstanding effects that:
the invention successfully clones the tobacco NbSMG7, and discovers that the gene has the function of resisting cucumber green mottle mosaic virus for the first time. By an agrobacterium transformation method, NbSMG7 gene is introduced into a target plant, and the NbSMG7 high-expression transgenic plant of the Nicotiana benthamiana can block the infection of cucumber green mottle mosaic virus through identification, so that the method has important production significance.
The application of the NbSMG7 gene in the invention in regulating plant antivirus and a transgenic plant cultivation method are further explained in the following description and specific examples in combination with the attached drawings.
Drawings
FIG. 1 shows the construction of YFP-NbSMG7 and the identification of vector expression. Wherein, (A) YFP-NbSMG7 vector construction scheme. 35S is a cauliflower mosaic virus strong constitutive promoter, can start the expression of a downstream fusion gene YFP (yellow fluorescent protein) -NbSMG7 (cloned target gene), and NOS is a transcription termination site; (B) confocal observation of YFP-NbSMG7 Agrobacterium tumefaciens infiltration inoculated 48 hours of the instant fluorescence of the Bunshi tobacco leaf; H2B-RFP indicates the nuclear location; the Merge column is the superposition of YFP, RFP and bright field; (C) western blot analysis of protein expression in Nicotiana benthamiana leaves from Agrobacterium infiltration inoculated with YFP-NbSMG7, ribulose diphosphate carboxylase large subunit (rbcL) stained with Ponceau S to indicate the same level of protein loading, Mock wild type Nicotiana benthamiana.
FIG. 2 is an identification of YFP-NbSMG7 transgenic plants. Wherein, (A) T1 generation YFP-NbSMG7 transgenic plants are compared with wild type Benyan phenotypes, Wt is wild type Benyan, Line2 and Line5 are YFP-NbSMG7 transgenic Benyan two different strains, and the transgenic plants have no difference with wild type phenotypes. (B) The PCR detection is carried out on the successfully cultured transgenic YFP-NbSMG7 plant DNA, and the target band is about 3700 bp. (C) Western blot analysis of protein expression in leaves from wild type, YFP-NbSMG7 transgenic plants (Line2, Line5) from Nicotiana benthamiana, respectively, the protein size was approximately 140kDa, and the large subunit of ribulose diphosphate carboxylase (rbcL) was stained with Ponceau S to indicate the same level of protein loading. Wt is wild type Ben-shi tobacco, and Line2 and Line5 are YFP-NbSMG7 transgenic Ben-shi tobacco two different strains.
FIG. 3 shows resistance analysis of YFP-NbSMG7 transgenic plants against Cucumber Green Mottle Mosaic Virus (CGMMV). Wherein, (A) the symptom graph 14 days after the Agrobacterium is infiltrated and inoculated with CGMMV in different strains YFP-NbSMG7-Line2 and YFP-NbSMG7-Line5 of wild type Bunsen tobaccos and YFP-NbSMG7 transgenic Bunsen, the virus symptoms of the wild type Bunsen are more serious; (B) and (3) analyzing the RNA accumulation of the CGMMV of the plant in 14 days in the step (A) by RT-qPCR, wherein the result shows that the YFP-NbSMG7 transgenic plant can obviously reduce the RNA accumulation of the CGMMV.
Detailed Description
A method for cultivating a cucumber green mottle mosaic virus resistant NbSMG7 transgenic plant specifically comprises the following steps:
(1) obtaining a Nicotiana benthamiana plant, extracting RNA from leaves of the Nicotiana benthamiana plant by using a Trizol method, removing genome DNA in an RNA sample, and performing reverse transcription to obtain cDNA;
(2) the primer pair NbSMG7-F and NbSMG7-R is shown as SEQ ID NO:2-3, cDNA is used as a template for PCR amplification, and the used primer sequence is as follows:
NbSMG7-F:atgatgaccattccaatgga,
NbSMG7-R:cacaaacaaacggccttc;
(3) constructing the amplification product on an n-YFP vector to obtain a YFP-NbSMG7 recombinant plasmid; as shown in FIG. 1 (A);
(4) transferring 1 mul of recombinant plasmid and 100 mul of agrobacterium-infected mixture into an electric shock cup, performing electric shock transformation by using an electric shock device at 2500V, adding LB culture medium, culturing for 2 hours, recovering, and then coating the mixture on a resistant culture medium to screen and obtain agrobacterium with YFP-NbSMG7 recombinant plasmid;
(5) infecting tobacco leaves with agrobacterium with recombinant plasmid, performing differentiation culture to obtain callus, performing rooting culture to obtain plantlet, and transferring for continuous culture;
(6) after the continuously cultured plantlets grow stably, taking a leaf sample, extracting DNA from plant leaves by using a CTAB method, performing PCR amplification by using the extracted DNA as a template, and determining whether YFP-NbSMG7 is successfully transformed; the primer sequences used were:
35S-F:cgcaagacccttcctctatataaggaa,
NbSMG 7-R: CACAAACAAACGGCCTTC, respectively; as shown in SEQ ID NO. 4 and SEQ ID NO. 3,
extracting total protein from the samples, performing SDS-PAGE gel electrophoresis, and performing Western blot by using a GFP antibody to determine that the YFP-NbSMG7 with a YFP fluorescent label is expressed in the plants. As shown in FIG. 2, the PCR detection shows that the target bands can be detected by Line2 and Line5 of the successfully cultured transgenic YFP-NbSMG7 plant DNA, the length is about 3.7kb, and YFP-NbSMG7 can be detected in the leaves of YFP-NbSMG7 transgenic plants (Line2 and Line5), and the protein size is about 140 kDa. And reserving seeds of transgenic tobacco successfully transformed and overexpressed with YFP-NbSMG 7.
(7) Wild-type Nb-WT and transgenic tobacco overexpressing YFP-NbSMG7 are sown, and after 20 days of sowing, control (Buffer) and CGMMV are inoculated. After 14 days of inoculation, virus symptoms were observed and virus accumulation was analyzed. As shown in FIG. 3A, both lines of YFP-NbSMG7 transgenic plants exhibited less viral symptoms relative to wild-type B.benthamiana. The qRT-PCR detection system has the advantage that the virus RNA accumulation of the leaf virus is obviously lower than that of the wild type Ben tobacco, and the virus RNA accumulation of the two transgenic strains is shown in figure 3B.
The experimental results show that: the NbSMG7 overexpression plant obtained by the agrobacterium genetic transformation method can obviously reduce the infection of cucumber green mottle mosaic virus and inhibit diseases caused by the cucumber green mottle mosaic virus.
The above-mentioned embodiments are merely illustrative of the preferred embodiments of the present invention, and do not limit the scope of the present invention, and various modifications and improvements of the technical solution of the present invention by those skilled in the art should fall within the protection scope defined by the claims of the present invention without departing from the spirit of the present invention.
Sequence listing
<110> institute of plant protection of Chinese academy of agricultural sciences
Application of <120> Nicotiana benthamiana NbSMG7 gene in regulation and control of plant virus resistance and transgenic plant cultivation method
<130> DS201-050
<160> 4
<170> SIPOSequenceListing 1.0
<210> 1
<211> 2982
<212> DNA
<213> NbSMG7(Artificial Sequence)
<400> 1
atgatgacca ttccaatgga tagtgctgct gatcaattgt ctcgcgagca agttcagcgc 60
ctctacaaca agaatgttga gttggagaat aaacggagaa aggcagcaca agctagagtt 120
ccttctgacc caagtgcatg gcaacaaatg cgagaaaact acgaatctat catccttgag 180
gataatgcct tctcagaaca acatgaaata gagtatgcct tgtggcagtt gcattacagg 240
agaattgagg aattgcgcgc acacttcaat gctgctgtaa gttctagtgt gtcaaccaat 300
tctcagaatg ggaaagttcc ccatcgtggt ggacctgatc gcgtcacaaa gatcaggaca 360
cagtttaaaa cttttctttc agaagcaaca ggattttatc atgatttgat gctaaaaatt 420
agggctaagt atggcttgca gctgggatat ttctctgatg atcacgaaaa tcagattcct 480
tcctctaaag atggtaataa atctgtggag gtgaagaaag gattgatatc ctgccatcgt 540
tgtttgattt accttggcga tcttgctcgg tacaaaggct tatatggtgt gggtgattcc 600
aaagcttgtg attttgcggc tgcttcgagt tattacctgc aagcttcttc actctggcct 660
tcaagtggca atcctcatca ccagcttgca atactggctt cctattccaa tgatgagctt 720
gtggctattt atcgctattt tcgcagtctt gcgatagaaa gcccttttgc cacggcaagg 780
gataacttga tcattgcatt tgagaagaac cgtcagtgtt actctcaact tgtgggggat 840
actaaagctt cctccaccaa ggccgtacgt cctcgtacaa ctggcgaagg aagaagcaaa 900
ggagaaacga ggtatccact gaaagatggt agggttgaag caagttcagt ccaggaaaag 960
ggttttatgt ctgacatctt caaaaccttc agcacaagat ttgttcgatt gaatggtatt 1020
cttttcactc gcactagttt ggagactttt ggagaagtgc agtcgatggt taaaaatgat 1080
ctgcttgagc ttctctcctc tgggactgat gagaagtata attttggttc tgacgctgcc 1140
gactgtaaac tggcttttgt aaggcttgtg gccatcctaa tattcactgt tcataacgtg 1200
aataaggaaa gcgaaaacca gtcatatgct gagattttac aaagatcggt tcttctacag 1260
aatgcattta ctgctgtgtt tgagatgatg ggtcatgtag ttgaaagatg tatccagtta 1320
aatgatccca cgacaagctt ccttttgcca ggggttttgg tgtttgtaga atggttagcg 1380
agccgtcaag atgttgcact tggcaacgat ccagaagaga agcaaaccag ggctagatca 1440
tttttctgga agaactgcat tgctttcttt aataagcttt tgtctagtgg gtttaagttt 1500
gttgatgctg acaaggatga tacgtgcttc ttcaatatga acagatatga tgaaggagag 1560
agggatagtc gtcttgcatt acccgaggat tttgagctga gaggatttat accttttctt 1620
ccggcacaac ttatccttga tttttcaagg aaacattctt ttggtggtga tggtggtatc 1680
aaagagaaga aatcacgtct ccagaggata atagcagcag gaaaggctct tgctaatgtg 1740
gtccgtgttg gagaagaggg aatttatttt gacggtagag caaagaaatt catcattggc 1800
attgagcctc aagtatctga tgattgtgcg cttaattgct ccatggaagt tcccaaattg 1860
agtggtattg atttggagaa ttcagctgca gggcagttaa ctgtaggagc tctgcagcca 1920
aagcaacgat tgtatgtaga aggtgaggaa gaagacgagg taattgtttt taagccatcg 1980
gtggtgcaaa agcatgtgaa tggaagcgct tcaaacatga tgacctcaga aggttatgtt 2040
tctggtgtta gtgctgccag tgttcctcct ggggttagca tggcatctgt tggtctagga 2100
aatgaaatgg gtccattttc agctgcactt gatggattga ttatgcagag tgcagtacat 2160
gcttgtgcaa ggccaccctc aagtattgcc aataacggtg gccaatatat gcagcctatt 2220
caaccaagta cttcattgtg gtccgttgaa caagctgctc ttatgaatgg atttgccagc 2280
ttgaacatga taggaaatgg tccaactata atatctgagt tgcaagatca agtatttcca 2340
cctgtgccat attctgtccc ttttccccag tctgtcaatt ttggcacaag taatattcct 2400
gtgcatatcc cagatgctgc cataccatct aacttcagtt cactttcatc gtcagtagtt 2460
ggtattgata gcatgtcagt taagtcccca tcagtcatgt caacaggcat aaggaaaaat 2520
ccagttagca gacctattag gcatctgggc ccgcctccag gctttggttc tgttcctttg 2580
aaagtcctag aggagtcttc ttcagcaatg accataaaga atgaacatat tactcttcct 2640
cctgtggatg actatagctg gctggatgga tatcggttgc cttcatcaca tgagagcatt 2700
ggtttcaata actccattaa tcattcaacg cacaattacc actcaatgaa caagagtagt 2760
agctccgttg ggatggtgag ctttcctttc cctgggaagc aggtaaactc tctgcatgtg 2820
caaacaggga accagagagg ttgggaggac taccagatat ctgaacaatt aaaactgtac 2880
caggagcaac ctcagcaact ccagagtgga aaccaacagt ctgttgaact gcctcagcgg 2940
catgaaggac agtctctgtg ggaaggccgt ttgtttgtgt ga 2982
<210> 2
<211> 20
<212> DNA
<213> NbSMG7-F(Artificial Sequence)
<400> 2
atgatgacca ttccaatgga 20
<210> 3
<211> 18
<212> DNA
<213> NbSMG7-R(Artificial Sequence)
<400> 3
cacaaacaaa cggccttc 18
<210> 4
<211> 27
<212> DNA
<213> 35S-F(Artificial Sequence)
<400> 4
cgcaagaccc ttcctctata taaggaa 27
Claims (4)
1. The application of the NbSMG7 gene in regulating and controlling plant virus resistance is characterized in that: the virus is cucumber green mottle mosaic virus; the transcript sequence of the NbSMG7 is shown as SEQ ID NO. 1.
2. The use of the gene of NbSMG7 in the regulation of plant antiviral activity according to claim 1, wherein the gene comprises: by cloning NbSMG7 gene in the Bunsen tobacco, constructing the NbSMG7 gene into YFP-NbSMG7 vector with a fluorescent label, and infecting tobacco after transferring the YFP-NbSMG7 vector into agrobacterium, the obtained Bunsen tobacco overexpression YFP-NbSMG7 plant can obviously block the infection of cucumber green mottle mosaic virus.
3. A method for cultivating NbSMG7 transgenic plants resistant to cucumber green mottle mosaic virus is characterized in that: by an agrobacterium transformation method, introducing NbSMG7 gene into a target plant to obtain a Nicotiana benthamiana NbSMG7 high-expression transgenic plant; the transcript sequence of the NbSMG7 is shown as SEQ ID NO. 1.
4. The method of claim 3, comprising the steps of:
(1) obtaining a Nicotiana benthamiana plant, extracting RNA from leaves of the Nicotiana benthamiana plant by using a Trizol method, removing genome DNA in an RNA sample, and performing reverse transcription to obtain cDNA;
(2) the primer pair NbSMG7-F and NbSMG7-R is shown as SEQ ID NO:2-3, cDNA is used as a template for PCR amplification, and the used primer sequence is as follows:
NbSMG7-F:atgatgaccattccaatgga,
NbSMG7-R:cacaaacaaacggccttc;
(3) constructing the amplification product on an n-YFP vector to obtain a YFP-NbSMG7 recombinant plasmid;
(4) transferring 1 mul of recombinant plasmid and 100 mul of agrobacterium-infected mixture into an electric shock cup, performing electric shock transformation by using an electric shock device at 2500V, adding LB culture medium, culturing for 2 hours, recovering, and then coating the mixture on a resistant culture medium to screen and obtain agrobacterium with YFP-NbSMG7 recombinant plasmid;
(5) infecting tobacco leaves with agrobacterium with recombinant plasmid, performing differentiation culture to obtain callus, performing rooting culture to obtain plantlet, and transferring for continuous culture;
(6) after the continuously cultured plantlets grow stably, taking a leaf sample, extracting DNA from plant leaves by using a CTAB method, performing PCR amplification by using the extracted DNA as a template, and determining whether YFP-NbSMG7 is successfully transformed; the primer sequences used were:
35S-F:cgcaagacccttcctctatataaggaa,
NbSMG 7-R: CACAAACAAACGGCCTTC, respectively; as shown in SEQ ID NO. 4 and SEQ ID NO. 3,
extracting total protein from the samples, performing SDS-PAGE gel electrophoresis, and determining that the YFP-NbSMG7 with a YFP fluorescent label is expressed by the plants by using GFP antibody to perform Western blot; and reserving seeds of transgenic tobacco successfully transformed and overexpressed with YFP-NbSMG 7.
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